Acquisition of thermotolerance in Saccharomyces cerevisiae without heat shock protein hsp 104 and in the absence of protein synthesis.

Acquisition of thermotolerance in response to a preconditioning heat treatment at 40 degrees C was studied in mutants of the yeast Saccharomyces cerevisiae lacking a specific heat shock protein or the ability to synthesize proteins at 40 degrees C. A mutant carrying a deletion of heat shock protein hsp 104 and the corresponding wildtype strain were both highly sensitive to heat stress at 50.4 degrees C without preconditioning but both acquired almost the same level of thermotolerance after 60 min of preconditioning. Both strains showed equal induction of trehalose-6-phosphate synthase and accumulated equal levels of trehalose during the treatment. The conditional mutant ts--187 synthesized no proteins during the preconditioning heat treatment but nevertheless acquired thermotolerance, albeit to a lesser degree than the corresponding wildtype strain. Induction of trehalose-6-phosphate synthase and accumulation of trehalose were reduced to a similar extent. These results show that acquisition of thermotolerance and accumulation of trehalose are closely correlated during heat preconditioning and are modulated by protein synthesis but do not require it.     

Heat shock-induced SRSF10 dephosphorylation displays thermotolerance mediated by Hsp27

Gene regulation in response to environmental stress is critical for the survival of all organisms. From Saccharomyces cerevisiae to humans, it has been observed that splicing of mRNA precursors is repressed upon heat shock. However, a mild heat pretreatment often prevents splicing inhibition in response to a subsequent and more severe heat shock, a phenomenon called splicing thermotolerance. We have shown previously that the splicing regulator SRSF10 (formerly SRp38) is specifically dephosphorylated by the phosphatase PP1 in response to heat shock and that dephosphorylated SRSF10 is responsible for splicing repression caused by heat shock. Here we report that a mild heat shock protects SRSF10 from dephosphorylation during a second and more severe heat shock. Furthermore, this "thermotolerance" of SRSF10 phosphorylation, like that of splicing, requires de novo protein synthesis, specifically the synthesis of heat shock proteins. Indeed, overexpression of one of these proteins, Hsp27, inhibits SRSF10 dephosphorylation in response to heat shock and does so by interaction with SRSF10. Our data thus provide evidence that splicing thermotolerance is acquired through maintenance of SRSF10 phosphorylation and that this is mediated at least in part by Hsp27.     

Molecular events associated with acquisition of heat tolerance by the yeast Saccharomyces cerevisiae

Abstract: The heat shock response is an inducible protective system of all living cells. It simultaneously induces both heat shock proteins and an increased capacity for the cell to wisthstand potentially lethal temperatures (an increased thermotolerance). This has lead to the suspicion that these two phenomena must be inexorably linked. However, analysis of heat shock protein function in Saccharomyces cerevisiae by molecular genetic techniques has revealed only a minority of the heat shock proteins of this organism having appreciable influences on thermotolerance. Instead, physiological perturbations and the accumulation of trehalose with heat stress may be more important in the development of thermotolerance during a preconditioning heat shock. Vegetative S. cerevisiae also acquires thermotolerance through osmotic dehydration, through treatment with certain chemical agents and when, due to nutrient limitation, it arrests growth in the GI phase of the cell cycle. There is evidence for the activities of the cAMP-dependent protein kinase and plasma membrane ATPase being very important in thermotolerance determination. Also, intracellular water activity and trehalose probably exert a strong influence over thermotolerance through their effects on stabilisation of membranes and intracellular assemblies. Future investigations should address the unresolved issue of whether the different routes to thermotolerance induction cause a common change to the physical state of the intracellular environment, a change that may result in an increased stabilisation of cellular structures through more stable hydrogen bonding and hydrophobic interactions.     

Interleukin-6 induces thermotolerance in cultured Caco-2 cells independent of the heat shock response

In recent studies, induction of the heat shock response increased IL-6 production in gut mucosa in vivo and in cultured Caco-2 cells in vitro. The heat shock response is associated with increased survival of cells exposed to otherwise lethal hyperthermia, so called thermotolerance, but the role of IL-6 in the induction of thermotolerance is not known. We tested the hypothesis that treatment of cultured Caco-2 cells with IL-6 results in the development of thermotolerance. Cells were treated with human recombinant IL-6 for 1h followed by 3 h recovery in cytokine-free medium whereafter cells were exposed to heat stress (48 degrees C for 2 h). In untreated cells, the heat stress resulted in an approximately 80% cell death. In cells treated with IL-6, cell viability after heat stress was significantly improved and was doubled at an IL-6 concentration of 20 ng/ml. Treatment of the cells with other cytokines (IL-4, IL-10, IL-1beta, or TNFalpha) did not induce thermotolerance, suggesting that the effect of IL-6 may be specific for this cytokine. The induction of thermotolerance by IL-6 was blocked by an IL-6 receptor antibody, suggesting that the development of thermotolerance was receptor-mediated. Treatment of cells with IL-6 did not induce an heat shock response as suggested by unaltered heat shock protein 70 and 90 levels and unaffected heat shock factor DNA binding activity. In addition, the IL-6-induced thermotolerance was not inhibited by quercetin. The present study provides the first evidence of IL-6-induced thermotolerance and suggests that this effect of IL-6 is independent of the heat shock response.     

Induction of the heat shock response and translational thermotolerance in day 15 ovine trophectoderm

The objectives of this study were to determine the ability of trophectoderm from preimplantation ovine embryos to synthesize hsp70 in response to heat shock and to identify conditions which induce translational thermotolerance in this tissue. Day 15 embryos were collected, and proteins synthesized in 1.5-mm sections of trophectoderm were radioactively labeled with (35)S-methionine. One-dimensional SDS-PAGE gels, two-dimensional gel electrophoresis and Western blots were utilized to characterize the heat shock response and to examine the induction of translational thermotolerance. Increased synthesis of the 70 kDa heat shock proteins and a protein with an approximate molecular weight of 15 to 20 kDa was observed with heat shock (> or = 42 degrees C). Total protein synthesis decreased (P < 0.05) with increased intensity of heat shock. At 45 degrees C, protein synthesis was suppressed with little or no synthesis of all proteins including hsp70. Recovery of protein synthesis following a severe heat shock (45 degrees C for 20 min) occurred faster (P < 0.05) in trophectoderm pretreated with a mild heat shock (42 degrees C for 30 min) than trophectoderm not pretreated with mild heat. In summary, trophoblastic tissue obtained from ovine embryos exhibit the characteristic "heatshock" response similar to that described for other mammalian systems. In addition, a sublethal heat shock induced the ability of the tissue to resume protein synthesis following severe heat stress. Since maintaining protein synthesis is crucial to embryonic survival, manipulation of the heat-shock response may provide a method to enhance embryonic survival.     

Histamine modulates the cellular stress response in yeast

The cellular stress response is a universal protective reaction to adverse environmental or microenvironmental conditions, such as heat and drugs, associated in part with the highly conserved heat shock proteins (HSPs). Histamine is a key inflammatory mediator derived from l-histidine that governs vital cellular processes beyond inflammation, while recent evidence implies additional actions in both prokaryotes and eukaryotes. This study explored the possible role of histamine in the heat shock response in yeast, an established experimental model for the pharmacological investigation of the cellular stress response. The response was evaluated by determining growth and viability of post-logarithmic phase grown yeast cultures after heat shock at 53°C for 30 min. Thermal preconditioning at 37°C for 2 h served as a positive control. The effect of histamine was investigated following long-term administration through the post-logarithmic phase of growth or short-term administration for 2 h prior to heat shock. Short-term treatment with 1 mM histamine resulted in de novo protein synthesis-dependent acquisition of thermotolerance, while lower doses or long-term administration of histamine failed to induce the heat-resistant phenotype. Preliminary investigation of HSP104, HSP70 and HSP60 expression by western blotting showed an increase of these proteins after thermal preconditioning. However, a differential HSP and tubulin expression appeared to underlie the response of yeast cells to histamine. In conclusion, histamine was capable of inducing the adaptive phenotype, while the contribution of HSPs and tubulin and the potential implications remain largely elusive.     

Protein denaturation during heat shock and related stress. Escherichia coli beta-galactosidase and Photinus pyralis luciferase inactivation in mouse cells

In an attempt to question the toxic effect of heat shock and related stress, we have studied the activity of reporter enzymes during stress. Escherichia coli beta-galactosidase and Photinus pyralis luciferase were synthesized in mouse and Drosophila cells after transfection of the corresponding genes. Both enzymes are rapidly inactivated during hyperthermia. The corresponding polypeptides are not degraded but become insoluble even in the presence of non-ionic detergents. The heat inactivation is more dramatic in vivo within the living cell than in vitro, in a detergent-free crude cell lysate. The extent of enzyme inactivation at a given temperature depends on the cell type in which the enzyme is expressed. Luciferase is inactivated at lower temperatures within Drosophila cells than within mouse cells, whereas beta-galactosidase is inactivated at higher temperatures in E. coli than in mouse cells. A "priming" heat shock confers a transient increased resistance (thermotolerance) of cells against a second "challenging" heat shock. Enzyme inactivation during heat shock or exposure of the cells to ethanol is attenuated in heat shock-primed cells. A comparable thermoprotection is raised by a priming heat shock for both luciferase activity and protein synthesis. Thus, the study of reporter enzyme inactivation is a promising tool for understanding the molecular basis of the toxicity of heat shock and related stress as well as the mechanisms leading to thermotolerance.     

Stress proteins and cross-protection by heat shock and salt stress in Bacillus subtilis.

Bacillus subtilis induced a set of general stress proteins in response to a salt or heat stress. Cells subjected to a mild heat stress showed a protective response which enabled them to survive otherwise lethal temperatures (e.g. 52 degrees C). In a similar way bacteria were enabled to survive toxic concentrations of NaCl by pretreatment with lower salt concentrations. A mild heat shock induced a cross-protection against lethal salt stress. The pretreatment of cells with low salt, however, was less effective in the induction of thermotolerance than a preceding mild heat stress. Three stress proteins were identified on the basis of their N-terminal amino acid sequences as homologues of GroEL, DnaK and ClpP of Escherichia coli. The role of general and specific stress proteins in the induction of thermotolerance/salt tolerance and cross-protection is discussed.     

Translational thermotolerance provided by small heat shock proteins is limited to cap-dependent initiation and inhibited by 2-aminopurine

Heat shock results in inhibition of general protein synthesis. In thermotolerant cells, protein synthesis is still rapidly inhibited by heat stress, but protein synthesis recovers faster than in naive heat-shocked cells, a phenomenon known as translational thermotolerance. Here we investigate the effect of overexpressing a single heat shock protein on cap-dependent and cap-independent initiation of translation during recovery from a heat shock. When overexpressing alphaB-crystallin or Hsp27, cap-dependent initiation of translation was protected but no effect was seen on cap-independent initiation of translation. When Hsp70 was overexpressed however, both cap-dependent and -independent translation were protected. This finding indicates a difference in the mechanism of protection mediated by small or large heat shock proteins. Phosphorylation of alphaB-crystallin and Hsp27 is known to significantly decrease their chaperone activity; therefore, we tested phosphorylation mutants of these proteins in this system. AlphaB-crystallin needs to be in its non-phosphorylated state to give protection, whereas phosphorylated Hsp27 is more potent in protection than the unphosphorylatable form. This indicates that chaperone activity is not a prerequisite for protection of translation by small heat shock proteins after heat shock. Furthermore, we show that in the presence of 2-aminopurine, an inhibitor of kinases, among which is double-stranded RNA-activated kinase, the protective effect of overexpressing alphaB-crystallin is abolished. The synthesis of the endogenous Hsps induced by the heat shock to test for thermotolerance is also blocked by 2-aminopurine. Most likely the protective effect of alphaB-crystallin requires synthesis of the endogenous heat shock proteins. Translational thermotolerance would then be a co-operative effect of different heat shock proteins.     

Induction of thermotolerance and enhanced heat shock protein synthesis in chinese hamster fibroblasts by sodium arsenite and by ethanol

Synthesis of a family of proteins called “heat shock” proteins is enhanced in cells in response to a wide variety of environmental stresses. This suggests that these proteins may have functions essential to cell survival under stressful conditions. A causative relationship between heat shock protein synthesis and development of thermotolerance would imply that agents known to induce heat shock protein synthesis, such as sodium arsenite, also induce thermotolerance. Conversely, agents known to induce thermotolerance, such as ethanol, would also enhance heat shock protein synthesis. To test this hypothesis, I have examined the effect of sodium arsenite or ethanol treatment on protein synthesis and cell survival in Chinese hamster ovary HA-1 cells. After either sodium arsenite or ethanol treatment, the synthesis of heat shock proteins was greatly enhanced over that of untreated cells. In parallel, cell survival was increased as much as 10⁴-fold when cells exposed to either agent were challenged by a subsequent heat treatment. The synthesis of heat shock proteins correlated well with the development of thermotolerance. A qualitative analysis of individual proteins suggests that the synthesis of 70,000 and 87,000 molecular weight proteins most closely mirrored the development of thermotolerance. The results, therefore, strongly reinforce the hypothesis that a causal relationship exists between the enhanced synthesis of heat shock protein and cell survival under specific stresses.     

Thermotolerance is independent of induction of the full spectrum of heat shock proteins and of cell cycle blockage in the yeast Saccharomyces cerevisiae.

Cells of the yeast Saccharomyces cerevisiae are known to acquire thermotolerance in response to the stresses of starvation or heat shock. We show here through the use of cell cycle inhibitors that blockage of yeast cells in the G1, S, or G2 phases of the mitotic cell cycle is not a stress that induces thermotolerance; arrested cells remained as sensitive to thermal killing as proliferating cells. These G1- or S-phase-arrested cells were unimpaired in the acquisition of thermotolerance when subjected to a mild heat shock by incubation at 37 degrees C. One cell cycle inhibitor, o-phenanthroline, did in fact cause cells to become thermotolerant but without induction of the characteristic pattern of heat shock proteins. Thermal induction of heat shock protein synthesis was unaffected; the o-phenanthroline-treated cells could still synthesize heat shock proteins upon transfer to 37 degrees C. Use of a novel mutant conditionally defective only for the resumption of proliferation from stationary phase (M. A. Drebot, G. C. Johnston, and R. A. Singer, Proc. Natl. Acad. Sci. USA 84:7948-7952, 1987) indicated that o-phenanthroline inhibition produces a stationary-phase arrest, a finding which is consistent with the increased thermotolerance and regulated cessation of proliferation exhibited by the inhibited cells. These findings show that the acquired thermotolerance of cells is unrelated to blockage of the mitotic cell cycle or to the rapid synthesis of the characteristic spectrum of heat shock proteins.     

The molecular chaperone Hsp78 confers compartment-specific thermotolerance to mitochondria

Hsp78, a member of the family of Clp/Hsp100 proteins, exerts chaperone functions in mitochondria of S. cerevisiae which overlap with those of mitochondrial Hsp70. In the present study, the role of Hsp78 under extreme stress was analyzed. Whereas deletion of HSP78 does not affect cell growth at temperatures up to 39 decrees C and cellular thermotolerance at 50 degrees C, Hsp78 is crucial for maintenance of respiratory competence and for mitochondrial genome integrity under severe temperature stress (mitochondrial thermotolerance). Mitochondrial protein synthesis is identified as a thermosensitive process. Reactivation of mitochondrial protein synthesis after heat stress depends on the presence of Hsp78, though Hsp78 does not confer protection against heat-inactivation to this process. Hsp78 appears to act in concert with other mitochondrial chaperone proteins since a conditioning pretreatment of the cells to induce the cellular heat shock response is required to maintain mitochondrial functions under severe temperature stress. When expressed in the cytosol, Hsp78 can substitute for the homologous heat shock protein Hsp104 in mediating cellular thermotolerance, suggesting a conserved mode of action of the two proteins. Thus, proteins of the Clp/Hsp100-family located in the cytosol and within mitochondria confer compartment-specific protection against heat damage to the cell.     

OGT functions as a catalytic chaperone under heat stress response: a unique defense role of OGT in hyperthermia

Protein O-GlcNAcylation is proceeded by O-linked GlcNAc transferase (OGT) in nucleocytoplasm and is involved in many biological processes although its physiological role is not clearly defined. To identify the functional significance of O-GlcNAcylation, we investigated heat stress effects on protein O-GlcNAcylation. Here, we found that protein O-GlcNAcylation was significantly increased in vivo during acute heat stress in mammalian cells and simultaneously, the enhanced protein O-GlcNAcylation was closely associated with cell survival in hyperthermia. Our results demonstrate that hyperthermal cytotoxicity may considerably be facilitated under the condition of insufficient level of protein O-GlcNAcylation inside cells. Furthermore, OGT reaction might be crucial for triggering thermotolerance to recover hyperthermal sensitivity without particular induction of heat shock proteins (hsps). Thus, we propose that OGT can respond rapidly to heat stress through the enhancement of nucleocytoplasmic protein O-GlcNAcylation for a rescue from the early phase of hyperthermal cytotoxicity.     

Heat shock response of the rat lens

The sequence relationship between the small heat shock proteins and the eye lens protein alpha-crystallin (Ingolia, T. D., and E. E. Craig, 1982, Proc. Natl. Acad. Sci. USA, 79: 2360-2364) prompted us to subject rat lenses in organ culture to heat shock and other forms of stress. The effects on protein synthesis were followed by labeling with [35S]methionine and analysis by one- and two-dimensional gel electrophoresis and fluorography. Heat shock gave a pronounced induction of a protein that could be characterized as the stress protein SP71. This protein probably corresponds to the major mammalian heat shock protein hsp70. Also two minor proteins of 16 and 85 kD were induced, while the synthesis of a constitutive heat shock-related protein, P73, was considerably increased. The synthesis of SP71 started between 30 and 60 min after heat shock, reached its highest level after 3 h, and had stopped again after 8 h. In rat lenses that were preconditioned by an initial mild heat shock, a subsequent shock did not cause renewed synthesis of SP71. This effect resembles the thermotolerance phenomenon observed in cultured cells. The proline analogue azetidine-2-carboxylic acid, zinc chloride, ethanol, and calcium chloride did not, under the conditions used, induce stress proteins in the rat lens. Sodium arsenite, however, had very much the same effects as heat shock. Calcium ionophore A23187 specifically and effectively induced the synthesis of the glucose-regulated protein GRP78. No special response to stress on crystallin synthesis was noticed.     

Abnormal proteins as the trigger for the induction of stress responses: heat, diamide, and sodium arsenite

Thermotolerance and synthesis of heat shock proteins are induced in cells in response to a variety of environmental stresses. We examined the suggestion of Hightower (1980) that modifications of intracellular proteins may be the triggering event that induces heat shock protein synthesis and thermotolerance. We did so by modifying cellular proteins, using diamide, a sulfhydryl oxidizing agent, and dithio-bis (succinimidyl propionate), an agent that cross-links bifunctional amino groups. Both of these agents induced heat shock proteins and thermotolerance in CHO (HA-1) cells. Furthermore, we observed cross-resistance and self-tolerance with three seemingly unrelated stimuli (diamide, heat, and sodium arsenite). This observation suggests that the induction of protective responses to these stimuli is mediated by a common mechanism. The results support the hypothesis that production of abnormal proteins by various stresses induces the stress responses as well as tolerance.     

Role of priming stresses and Hsp70 in protection from ischemia-reperfusion injury in cardiac and skeletal muscle

Ischemia-reperfusion injury limits the survival of muscle involved in tissue trauma or transfers during microsurgical reconstruction. Priming stresses such as ischemic preconditioning or mild hyperthermia have frequently been associated with improved survival of ischemic-reperfused cardiac muscle, such protection coinciding with induction of the stress-related heat shock protein 70 (Hsp70). Little is known about the response of skeletal muscle to priming stresses. This review summarizes the current knowledge on the use of priming stresses as protective strategies against the consequences of ischemia-reperfusion in cardiac and skeletal muscle and the potential role of Hsp70.     

Chemical Induction of Stress Proteins Does Not Induce Splicing Thermotolerance under Conditions Producing Survival Thermotolerance

Cell survival during a severe heat stress can be enhanced when heat shock proteins are induced prior to the severe heat treatment. Induction can be accomplished either by heat or chemical treatments. The increase in survival at these severe elevated temperatures after pretreatment has been referred to as thermotolerance, which we now refer to as survival thermotolerance. It has also been shown previously that mild heat treatment allows splicing in cells subjected to a severe heat treatment, now referred to as splicing thermotolerance. The experiments shown here demonstrate that even though chemical induction of the heat shock proteins leads to survival thermotolerance, this same treatment does not induce splicing thermotolerance. These are the first results that demonstrate at least two distinct aspects of thermotolerance.